Waveguide Bragg Grating for Fault Localization in PON

Femtosecond laser direct inscription is a technique especially useful for prototyping purposes due to its distinctive advantages such as high fabrication accuracy,true 3D processing flexibility,and no need for mold or photomask.In this paper,we demonstrate the design and fabrication of a planar lightwave circuit(PLC)power splitter encoded with waveguide Bragg gratings(WBG)using a femtosecond laser inscription technique for passive optical network(PON)fault localization application.Both the reflected wavelengths and intervals of WBGs can be conveniently tuned.In the experiment,we succeeded in directly inscribing WBGs in 1×4 PLC splitter chips with a wavelength interval of about 4 nm and an adjustable reflectivity of up to 70% in the C-band.The proposed method is suitable for the prototyping of a PLC splitter encoded with WBG for PON fault localization applications.

Fabrication and Evaluation of Bragg Gratings on Optimally Designed Silicon-on-Insulator Rib Waveguides Using Electron-Beam Lithography

The fabrication of Bragg gratings on silicon-on-insulator （SOI） rib waveguides using electron-beam lithography is presented. The grating waveguide is optimally designed for actual photonic integration. Experimental and theoretical evaluations of the Bragg grating are demonstrated. By thinning the SOl device layer and deeply etching the Bragg grating, a large grating coupling coefficient of 30cm^-1 is obtained.

Temperature-and Strain-Compensated Directional Curvature Sensor Based on Bragg Gratings in Three-Core Fiber with Bridged Waveguides

Fiber-based curvature sensors,especially those capable of discerning the direction of curvature,have attracted more and more interest due to their promising applications in structural health monitoring,high-precision measurement,medical and biological diagnosis-treat instruments,and so on.Here,we propose and demonstrate a compact directional curvature sensor that comprises two bridged waveguides and three Bragg gratings in a section of three-core fiber(TCF).Both the waveguides and gratings are integrated by femtosecond laser micromachining method.The waveguides,connecting the TCF outer cores to the lead-in single-mode fiber core,function as beam couplers to realize simultaneous interrogation of all three gratings without any separate fan-in/out component.Owing to the spatial specificity,the outer-core gratings exhibit high and direction-dependent sensitivity to curvature,whereas the central-core grating is nearly insensitive to curvature but shows similar sensitivities to ambient temperature and axial strain as the outer-core gratings.It can be used to compensate the cross impact of temperature and strain when the outer-core gratings are applied for curvature detection.Moreover,the wavelength interval between two outer-core gratings is also proposed as an indicator for curvature sensing.It features with a much higher sensitivity to curvature and reduced sensitivities to temperature and axial strain.The corresponding maximum sensitivity to curvature is as high as 191.89 pm/m-1,while the sensitivities to temperature and strain are only 0.3 pm/℃and 0.0218 pm/με,respectively.Therefore,our proposed device provides a compact and robust all-infiber solution for directional curvature sensing.It not only offers high sensitivity and accuracy but also immunity to temperature and axial strain fluctuations,making it a promising tool for a wide range of applications.

Study of Deep-etched Glass Waveguide Grating

Photoresist grating was fabricated by holography, and it was used in the mask of ion etching. The groovy depth of the etched glass grating was 1.6μm. The glass waveguide was formed by K^+/Na^+ ion exchanging. The laser beam of 633nm was coupled in the waveguide by a prism at one end, then, it passed through the grating and came out of the waveguide at other end. In the experiment, the Bragg diffraction with several orders was observed. The first order Bragg diffraction had the highest efficiency of 90 percent.

Chalcogenide As₂S₃Sidewall Bragg Gratings Integrated on LiNbO₃Substrate

This paper introduces the design and applications of integrated As2S3 sidewall Bragg gratings on LiNbO3 substrate. The grating reflectance and bandwidth are analyzed with coupled-mode theory. Coupling coefficients are computed by taking overlap integration. Numerical results for uniform gratings, phase-shifted gratings and grating cavities as well as electro-optic tunable gratings are presented. These integrated As2S3 sidewall gratings on LiNbO3 substrate provide an approach to the design of a wide range of integrated optical devices including switches, laser cavities, modulators, sensors and tunable filters.

光纤Bragg光栅温度与应力的测量分析

采用了一种基于等强度悬臂梁的双光纤栅组合法,实现温度与应力的同时测量。选用同一批次生产的参数一致的两根光纤Bragg光栅,将其分别粘贴在等强度梁的上下表面,通过梁上下光栅所受的应力大小相等而方向相反,产生两个反射峰来实现温度与应力的同时测量。通过实验测得光栅温度灵敏度系数为0.1346 nm/℃,梁上下光栅误差仅为0.0001 nm/℃;应力灵敏度系数分别为0.4085nm/N,-0.4089nm/N,误差也仅为0.0004 nm/N。实验结果表明该方法切实可行,制作工艺简单,克服了传统双光栅组合法难以保证测量位置准确性的缺点。

各向异性材料包层光纤Bragg光栅的反射谱

应用数值解法对包层为单轴晶体材料且其光轴平行于光纤轴的光纤功率限制因子进行了理论模拟,并从模式特性出发解释了k_(cl)对该类光纤Bragg光栅的反射率的影响。计算结果表明:对于HE_(11)模,各向同性材料包层光纤中的能量比单轴晶体材料包层光纤中的能量更容易集中在纤芯中传输,而且集中程度与k_(cl)的取值有关;各向异性材料包层比各向同性材料包层的光纤Bragg光栅的反射率要高;此类光纤Bragg光栅的反射率主要是由光纤纤芯和包层中能量分布决定的。

基于参考传感器的OPGW线路低噪声覆冰舞动监测

针对外场环境下光纤复合架空地线舞动周期监测困难等问题,提出一种基于参考传感器输入的弱反射光栅低噪声舞动监测阵列,通过理论模型推导了参考传感器及监测传感器信号模型及自适应滤波器信号处理步骤,并基于不同相关系数的噪声输入进行仿真,对比分析了监测传感器的降噪效果,最后将低噪声分布式弱反射光栅舞动监测系统布设于西部某自治州220 kV输电线路。外场实验结果表明,经过参考传感器构建输入信号实现自适应滤波后,平均噪声功率谱密度在100 Hz带宽内降低6.34 dB,且阵列监测强度图谱经过算法优化后,能够明显观测到监测档距内呈现约100 m舞动周期事件。该研究成果为进一步完善典型事件分类数据处理及模式识别数据库创造了一定条件,有一定的工程应用前景。

UV写入锗掺杂溶胶-凝胶玻璃Bragg光栅的制备

利用相位掩膜技术，用ＫｒＦ准分子紫外激光束（波长为２４８ｎｍ），在锗掺杂溶胶－凝胶玻璃平面波导中直接写入了Ｂｒａｇｇ光栅并对光栅的特性进行了测试与表征．

基于Bragg光栅的超高消光比SOI波导偏振器设计

波导偏振器是片上集成相干光学系统中的关键器件之一,超高消光比、低损耗、紧凑型波导偏振器的设计一直是研究的热点。基于绝缘体上硅平台的倾斜Bragg光栅被用于实现超高消光比波导偏振器结构。利用一维光子晶体能带理论分别计算TE和TM模式光的能带结构分布,选择TE模式禁带与TM导带重叠带隙设计光栅,可实现TM模式低损传输,而TE模式被Bragg光栅高效反射,从而产生超高偏振消光比。3D FDTD仿真表明:16μm倾斜Bragg光栅波导偏振器可在中心波长1550 nm附近70 nm的带宽内,实现大于37 dB的超高消光比,器件的损耗小于0.64 dB;进一步增加光栅周期数,当长度为25μm时,消光比可提高至46 dB。Bragg光栅倾斜角与刻蚀宽度偏差仿真表明:设计的结构加工误差容限较大,同时该结构仅需一次曝光刻蚀,工艺流程简单。

槽型相移布拉格光栅微环谐振器及其传感特性

为实现高灵敏度及高品质因数的折射率传感特性,设计了一种基于槽型相移布拉格光栅的微环谐振器结构。该结构由槽型直波导内嵌相移布拉格光栅耦合单实波导微环构成。结构中离散态光模式与连续态光模式相互干涉产生了Fano共振。利用传输矩阵法量化谐振器中各部分的光场分布,分析系统的传输原理。采用时域有限差分法对提出的器件结构进行仿真模拟,并对结构物理参数进行优化。模拟结果表明该结构的品质因数达到25729,比传统微环谐振器提高了3倍以上,消光比为18.65 dB,高出传统微环谐振器6.46 dB,折射率灵敏度达到122 nm/RIU,且该谐振器结构简单。所提出的结构在传感应用中具有一定的优势。

基于AWG的多通道光纤光栅传感解调系统

设计开发了一种基于陈列波导光栅（AWG）的多通道光纤光栅解调系统. 该系统由宽带光源、隔离器、耦合器、光环路器、光纤布拉格光栅（FBG）传感器、AWG、光电探测电路、调理放大电路、低通滤波电路和ARM控制电路等组成,采用光强法解调技术,对FBG 传感器的温度进行精确测量. 实验结果表明：该解调系统测量误差不大于±0.1 ℃,FBG 中心波长解调范围为1 545.30-1 560.50 nm, 可实现对4 通道的32 个FBG 传感器同时测量.

基于膜片的光纤布拉格光栅压力传感器的研究

理论分析了光纤布拉格光栅的压力传感特性,给出了光纤布拉格光栅的中心波长与压力的关系以及压力灵敏度系数的表达式,并将光纤布拉格光栅纵向粘贴在白行设计型号为ZXYC01的平面膜片上进行了压力实验。实验结果表明光纤布拉格光栅压力灵敏度系数46 pm／MPa左右,其测量精度为0．5％F．S,而理论的压力灵敏度系数为51 pm／MPa左右,实验值和理论值基本相符,它们分别是裸光纤布拉格光栅压力灵敏度系数的23和26倍。同时发现光纤布拉格光栅的中心波长与压力变化有着良好的线性关系和很高的相关系数并且迟滞现象较小。

基于偏振模干涉的光纤光栅动态应变解调系统

基于保偏光纤中正交偏振模干涉,提出了一种简单、新颖的光纤光栅动态应变解调系统,并且通过实验证实了该方案的可行性。该解调系统光学核心部分仅由一段带有反射镜的高双折射光纤和一个光纤起偏器构成。实验中动态应变解调分辨率达到了0.5nε/(Hz)^(1/2),频率范围为0.1～7.9kHz微纳幅度振动信号获得了保真拾取。实验表明,该系统适合宽频率范围、微纳幅度的动态应变检测,为光纤光栅传感提供了一种简单、经济、适用范围更广的解调方案。

单光纤光栅的温度、压力双参量测量分析

介绍了一种以悬臂梁为基底,单光纤光栅为传感元件,测量温度和压力的方法。分析了温度和波长的非线生关系对测量结果的影响,给出了布拉格共振波长与温度的线性及非线性的适用范围。光纤光栅的裸光栅部分和预应变部分波长与温度的线性适用范围分别为:-11.2℃～89℃,22.5℃～62.5℃。在此测量范围内,温度和压力响应曲线具有良好的线性。相应的压力灵敏度系数和温度灵敏度系数分别为:0 nm/N,0.4082 nm/N,0.0128 nm/℃,0.1346 nm/℃。结果表明,该方法简单易行,为温度和压力的实际测量提供了便利。

平面波导阵列布喇格光栅及其光辐照制作方法

本文提出了一种新的平面波导阵列布喇格光栅结构,并给出了在光敏感材料中制作这种波导光栅结构的全息光辐照方法.以LiNbO3∶Fe晶体作为光敏感材料,用不同空间频率的双光束干涉条纹辐照后,通过数字全息技术对晶体的光致折射率分布测量和进行的导波衍射测试结果表明,利用这种光辐照方法在光敏感材料中制作平面波导阵列全息布喇格光栅是完全可行的.其显著的导波衍射现象表明,如果在平面波导阵列中制作多重布喇格光栅,有可能使其成为超密集波分复用(UDWDM)系统中波长复用/解复用的核心器件.

纵向应力法制作双波长布喇格光栅

介绍了一种用一个均匀相位模板制作双波长布喇格光栅的方法;对这种方法制作的双波长布喇格光栅进行了理论分析,用矩阵分析法,对其进行了数值模拟。采用了移动曝光技术,通过调节所加应力的大小、光栅长度及曝光次数可以控制两个布喇格波长的间隔和反射率;写制了一个双波长光栅,两个透射峰均为19.5 dB,两个布喇格波长的间隔为0.78 nm。

基于AWG的波分/时分复用FBG传感器网络研究

为了充分利用传感器网络在频域和时域上的丰富资源,提出了一种采用WDM/TDM的网络复用技术的新型分布式FBG传感器网络设计方案。将FBG传感器利用阵列波导光栅(AWG)进行波分复用,并利用程控光开关对波分复用信道中的每一个FBG传感器进行时分复用。网络中的传感器数量可达几百只。以可调法布里—珀罗(F-P)滤波器和数字信号处理器为核心的解调模块,通过布设的参考FBG能够对F-P滤波器特征曲线进行实时校正,提高了解调准确度。传感过程实现了自动化。该传感器网络可以对矿井、地下隧道等危险环境进行实时温度测量、预警,具有很好的应用前景。

导波光学氢敏传感器研究进展

为了了解光学氢敏传感器研究与现状 ,我们介绍了导波光学氢敏传感器的主要应用场合和氢敏感膜的结构与镀膜工艺 ,对有代表性的光纤微透镜型、表面等离子共振光纤型、光纤倏逝波场型、光纤光栅和集成波导型氢敏传感器的结构及性能做了详细的分析 ,并对导波光学氢敏传感器的未来发展做了展望。

编码式光纤光栅传感阵列解调方案的论证

介绍了编码式光栅传感阵列的结构及其传感信号的特点。采用梳状结构对编码式光纤光栅传感阵列进行解调,利用被测光谱通过阵列波导光栅不同通道时输出的不同光强的比值确定被测光的波长。该文分别从理想状态和存在背景反射的状态论证了本文提出的方案的可行性,分析了噪声引起的误差。该系统不但适合于解调大容量的波长信息,而且在解调时不存在任何机械移动部分便可以快速、同时测量多个波长。